Quantum computing: Difference between revisions
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Quantum computers (QCs) can process vastly more information, faster, compared with conventional (binary) computers. | |||
Quantum computers can process vastly more information, faster, compared with conventional (binary) computers. | |||
Quantum computers are framed around ''qubits'', rather than the ''bits'' which are the basis of conventional computers. | Quantum computers are framed around ''qubits'', rather than the ''bits'' which are the basis of conventional computers. | ||
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#Superposition | #Superposition | ||
#Entanglement | #Entanglement | ||
Among other applications, quantum computing has the potential to break existing encryption systems, such as RSA encryption, but also to create more secure encryption systems. | |||
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* [[Quantum]] | * [[Quantum]] | ||
*[[Qubit]] | *[[Qubit]] | ||
*[[RSA encryption]] | |||
*[[Superposition]] | *[[Superposition]] | ||
[[Category:Technology]] | [[Category:Technology]] |
Latest revision as of 12:35, 3 December 2022
Quantum computers (QCs) can process vastly more information, faster, compared with conventional (binary) computers.
Quantum computers are framed around qubits, rather than the bits which are the basis of conventional computers.
Quantum computing is based on two key attributes of quantum systems:
- Superposition
- Entanglement
Among other applications, quantum computing has the potential to break existing encryption systems, such as RSA encryption, but also to create more secure encryption systems.